Handheld tool device with bracket holder unit for connection of two gear housings

ABSTRACT

A handheld tool device having at least one first gear housing, having at least one second gear housing, and having a bracket holder unit provided for connecting the two gear housings. It is provided that in the assembled state the bracket holder unit is situated at least in an area of contact of the gear housings in an opening of at least one of the gear housings.

RELATED APPLICATION INFORMATION

The present application claims priority to and the benefit of German patent application no. 10 2014 225 903.7, which was filed in Germany on Dec. 15, 2014, the disclosure of which is incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to a handheld device.

BACKGROUND INFORMATION

Handheld machine tools are known that have at least two gear housings, the housings being connected to one another by a screw connection, a locking connection, or a bracket holder unit.

SUMMARY OF THE INVENTION

The present invention is based on a handheld tool device having at least one first gear housing, having at least one second gear housing, and having a bracket holder unit (or bracket unit) that is provided for the detachable connection of the two gear housings.

It is proposed that, in the assembled state, the bracket holder unit is situated at least in a contact region of the gear housing, in an opening of at least one of the gear housings.

In the present context, a “handheld tool device” is to be understood in particular as at least a part, in particular a sub-assembly, of a handheld machine tool. In particular, the handheld tool device can also include the overall handheld machine tool. The handheld machine tool can in particular be fashioned as an arbitrary handheld machine tool considered useful by someone skilled in the art, which may be an electric handheld machine tool, such as a drilling machine, a drilling and/or impact hammer, a battery-operated drill, a battery-operated screwdriver, and/or a battery-operated drill/screwdriver.

In particular, the handheld tool device includes a gear housing unit that is provided in particular to accommodate and/or enclose, in an assembled state, at least one, advantageously exactly one, gear unit at least partially, advantageously at least in large part, and particularly completely. Here, the gear housing unit has in particular at least two gear housings, advantageously the first gear housing and the second gear housing, and is particularly formed by the first gear housing and the second gear housing. An outer contour of the gear housing unit and/or of the gear housing is advantageously fashioned at least substantially cylindrically, in particular in a circular cylindrical shape. The expression “at least in large part” is intended to be understood as covering in particular at least 51%, advantageously at least 60%, which may be at least 70%, and particularly at least 85%. An “at least substantially cylindrical” object is to be understood in particular as an object that deviates from a cylindrical object with a volume portion of a maximum of 30%, advantageously a maximum of 20%, and particularly a maximum of 10%. “Provided” is to be understood in particular as specifically designed and/or equipped. The statement that an object is provided for a particular function is to be understood in particular as meaning that this object fulfills and/or carries out this particular function in at least one state of use and/or operational state.

In addition, a “bracket holder unit” is to be understood in particular as a holding unit, which may be at least partly elastic, that has at least one holding element, in particular bracket-shaped, and is provided in particular to connect the first gear housing and the second gear housing to one another with a nonpositive fit and/or with a positive fit, and which may be detachably. The at least one holding element can have an arbitrary shape and/or contour considered useful by a person skilled in the art. Advantageously, the at least one holding element, in particular regarded in a side view, but at least substantially, is C-shaped, V-shaped, and/or U-shaped, and in particular has at least two, advantageously exactly two, bending edges, and in particular has at least two holding arms, and advantageously has at least one connecting web. Advantageously, the at least two holding arms and the at least one connecting web enclose an angle, in particular an acute angle, of at least 60° and a maximum of 90°, which may be less than 90°. Particularly, the bracket holder unit, in particular the at least one holding element, may be fashioned as a transport securing device. In this connection, a “partially elastic object” is to be understood in particular as an object, in particular a resetting object, that has at least a partial area that, in a normal operating state, can be elastically modified in its position by at least 0.1 mm, which may be by at least 0.5 mm, in particular may be by at least 1 mm, and that produces in particular a counter-force that is a function of a change of the position and may be proportional to the change, and which in particular counteracts the change. In particular, the elastic object is repeatedly deformable, in particular at least ten times and in particular without being damaged, and in particular automatically seeks to return to a basic shape after a deformation. In addition, a “detachable connection” between two objects is to be understood in particular as a connection that can be produced and/or separated reversibly without damage, in particular arbitrarily many times, which may be while avoiding damage to the objects. In addition, a “transport securing device” is to be understood in particular as a unit that is provided to connect the gear housings securely to one another at least during a transport, and that is advantageously provided to absorb, at least in large part, forces that occur during the transport. Advantageously, during operation axial forces occurring inside the gear housing, in particular coupling forces, are absorbed at least in large part, and which may be completely, by components differing from the bracket holder unit. In particular, the bracket holder unit is used at least substantially exclusively for securing the connection of the two gear housings during the transport. The bracket unit and/or the at least one holding element can in addition be made at least partly, which may be at least in large part, and particularly completely, of an arbitrary material considered useful by a person skilled in the art, such as plastic, rubber, and/or advantageously steel, in particular hardened steel, high-grade steel, and/or particularly spring steel.

In addition, an “opening” is to be understood in particular as a recess and/or material opening that in particular is situated on an outer side of the at least one gear housing, which may be in an edge area of the at least one gear housing, and in particular is provided to accommodate, at least partly, the bracket unit, in particular the at least one holding element.

Advantageously, the opening extends up to an outermost, in particular radial and/or axial, point of the at least one gear housing. Particularly, the first gear housing and the second gear housing may have an opening, in particular in the contact area of the gear housings. A “contact area of two objects is to be understood, in this context, in particular as an area of proximity around at least one point of contact of the objects. In addition, an area of proximity” is to be understood in particular as a spatial region that is formed from points that each have a distance of at most 20 mm, advantageously at most 10 mm, which may be at most 5 mm, and particularly at most 0.5 mm from a reference point and/or reference component.

In addition, the handheld tool device can have at least one handheld tool housing, at least one drive module, advantageously an electric motor, at least one, advantageously exactly one, gear unit, and/or at least one tool receptacle. The gear unit is advantageously fashioned as a multi-speed planetary gear, and in particular is situated, in an assembled state, at least partly, which may be at least in large part, and particularly completely inside the gear housing unit.

Through a corresponding design of the handheld tool device, in particular efficiency can be improved, in particular constructive space efficiency, cost efficiency, weight efficiency, and/or time efficiency, in particular during assembly. In addition, in particular a connection between the gear housings can be achieved that is neutral with respect to constructive space and is advantageously detachable, whereby in particular maintenance, assembly, and/or exchange of components can be facilitated.

Advantageously, the bracket holder unit and/or the at least one holding element is situated at least partially and may be at least in large part in a radial opening in at least one of the gear housings. In this context, a “radial opening” is to be understood in particular as an opening that extends in a radial direction, in particular in relation to the gear housing unit, to at least one of the gear housings, and/or to a tool axis of rotation of the handheld tool device. Particularly, the at least two gear housings each may have a radial opening in which the bracket holder unit and/or the at least one holding element is situated at least partially and may be at least in large part. In this way, in particular a bracket holder unit can be provided that is neutral with respect to constructive space.

If the bracket holder unit and/or the at least one holding element is situated at least partly, and may be at least in large part, in an axial opening of at least one of the gear housings, in particular a simple assembly can be achieved. In the present context, an “axial opening” is to be understood in particular as an opening that extends in an axial direction, in particular relative to the gear housing unit, to at least one of the gear housings and/or to the tool axis of rotation of the handheld tool device. Particularly, the at least two gear housings each may have an axial opening in which the bracket holder unit and/or the at least one holding element is situated at least partially and may be at least in large part.

In addition, it is proposed that the bracket holder unit and/or the at least one holding element is provided to exert an axial holding force on the at least two gear housings, and in particular, in an assembled state, on the at least two gear housings. In this way, in particular a secure connection can be ensured between the gear housings.

An assembly and/or disassembly that is particularly efficient with respect to time can be achieved in particular if the bracket holder unit, in particular the at least one holding element, is provided for a tangential assembly and/or disassembly. In the present context, a “tangential direction” is to be understood in particular as a direction that is oriented perpendicular to the axial direction and/or to the radial direction.

In an embodiment of the present invention, it is proposed that the bracket holder unit and/or the at least one holding element is situated at least partly, and may be at least in large part, in a bulge region of at least one of the gear housings. In the present context, a “bulge region” is to be understood in particular as a region of the gear housing that has a specific shape, and in particular that forms a bulge. In particular, the bulge region corresponds to a region having a larger radial extension compared to a surrounding area. In particular, the bulge region, and/or the bulge, is situated on an outer side of the gear housing, and extends at least partly, advantageously at least in large part, and particularly completely, in particular in annular fashion, around the at least one gear housing.

Particularly, the at least two gear housings each may have a bulge region in which the bracket holder unit and/or the at least one holding element is situated at least partially and may be at least in large part. In this way, in particular a stability of the connection can be increased.

The bulge region, in particular the bulge, may be provided for an axial fixing of the gear housing, in particular having the bulge region, in particular inside the handheld tool housing. In this way, in particular additional fastening arrangements can be omitted, which can reduce costs.

In addition, a handheld tool device is proposed having at least a first gear housing, having at least a second gear housing, and having a bracket holder unit that is provided for connecting the two gear housings, the bracket holder unit having, in particular in an assembled state, an axial extension less than 30 mm, which may be less than 20 mm, particularly less than 10 mm.

Advantageously, the at least one holding element has a longitudinal extension and/or, in particular in an assembled state, an axial extension less than 30 mm, which may be less than 20 mm, particularly less than 10 mm. In this way, a required constructive space can advantageously be reduced.

In an embodiment of the present invention, it is proposed that at least one of the gear housings has a ring gear bearing region in whose axial segment the bracket holder unit and/or the at least one holding element is situated, at least partially and which may be at least in large part. In particular, there exists at least one plane, advantageously a plurality of planes disposed parallel to one another, that is disposed in particular perpendicular to a longitudinal extension of the gear housing unit and/or of the tool axis of rotation, and which in particular contains at least one point of the ring gear bearing region and at least one point of the bracket holding unit. An object being situated in an “axial segment” of another object is to be understood in particular as meaning that the two objects are disposed so as to overlap axially. A “ring gear bearing region” is to be understood in the present context in particular as a region in which, in an assembled state, there is situated at least one, which may be exactly one, ring gear, in particular of the gear unit. In this way, in particular a simple and advantageously time-efficient assembly can be achieved.

In addition, it is provided that the ring gear bearing region is provided to accommodate a ring gear of a gear shift and/or to accommodate a ring gear of a torque coupling. In this way, in particular an advantageously compact design can be achieved.

If at least one of the gear housings has a securing bearing region in whose axial segment the bracket holder unit and/or the at least one holding element is situated at least partially, and may be at least in large part, an assembly can be further simplified. In particular, there exists at least one plane, advantageously a plurality of planes disposed in parallel, disposed in particular perpendicular to a longitudinal extension of the gear housing unit and/or of the tool axis of rotation, and which in particular contains at least one point of the securing bearing region and at least one point of the bracket holding unit. In the present context, a “securing bearing region” is to be understood in particular as a region in which, in an assembled state, there is situated at least one securing element, advantageously a securing ring and/or a securing plate. The at least one securing element is here in particular provided to secure and/or to fix components situated in at least one of the gear housings, in particular in the axial direction, in particular in a partially assembled state of the handheld tool device, whereby the gear housings can in particular be pre-assembled separately.

In addition, it is proposed that at least one of the gear housings has a bearing region of a locking element for a housing-fixed locking of a gear shift element, advantageously at least of the ring gear of the gear shift, the bracket holder unit and/or the at least one holding element being situated at least partially, and may be at least in large part, in the axial segment of the bearing region. In this way, in particular forces that occur during a gear shifting process can advantageously be absorbed by the bracket holder unit, and forces acting on other components of the handheld tool device can in this way be minimized.

In addition, a handheld tool device is proposed having at least one first gear housing, having at least one second gear housing, having a bracket holder unit provided for connecting the two gear housings, and having a support unit that is provided to relieve stress on the bracket holder unit, in particular of the at least one holding element, by absorbing at least a force occurring during operation inside at least one of the gear housings, in particular the coupling force, at least in large part and may be completely. Advantageously, the supporting unit here has at least one supporting element that is fashioned in particular as a securing ring, as is disclosed in particular in DE 10 2011 081 661 A1. The expression “to relieve stress on the bracket holder unit” is to be understood in particular as meaning that, in the absence of the support unit, the bracket holder unit would absorb the occurring axial force, in particular coupling force, in particular at least in large part. In this way in particular forces acting on the bracket holder unit can be reduced, whereby the bracket holder unit, in particular the at least one holding element, can advantageously be relieved of stress. In addition, the bracket holder unit, in particular the at least one holding element, can be advantageously fashioned in space-saving fashion and/or with light weight.

A particularly compact design can be achieved in particular if at least one of the gear housings, and/or the gear housings, is/are provided to accommodate an at least two-speed planetary gear.

In a particular embodiment of the present invention, it is proposed that the bracket holder unit has at least two holding elements fashioned separately from one another, provided to exert an axial holding force on the gear housing. Advantageously, the holding elements are fashioned analogously to one another. In particular, the bracket holder unit can also have exactly one holding element and/or at least three and/or at least four holding elements. In this way, a stability of the connection can advantageously be increased, whereby a secure connection can be ensured.

In particular in an assembled state, the at least two holding elements can be configured with an angle relative to one another of at least 90°, advantageously at least 120°, and particularly at least 160°. However, advantageously in an assembled state the at least two holding elements are configured radially opposite one another, in particular with respect to the gear housing unit, to at least one of the gear housings, and/or to the tool axis of rotation. Advantageously, here the holding elements are situated in the same axial segment and/or at the same axial height, in particular relative to the gear housing unit, to at least one of the gear housings, and/or to the tool axis of rotation. In this way, a constructively simple handheld tool device can be provided.

The handheld tool device according to the present invention is not intended to be limited to the above-described use and specific embodiment. In particular, the handheld tool device according to the present invention can have, in order to fulfill a manner of functioning described herein, a number of individual elements, components, and units differing from a number named herein.

Further advantages result from the following description of the drawing. The drawing shows two exemplary embodiments of the present invention. The drawing, the description, and the claims contain numerous features in combination. A person skilled in the art will usefully also regard the features individually, and combine them to form useful further combinations.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a handheld machine tool fashioned as a battery-operated drill/screwdriver, having an at least partly removed handheld tool housing, and having a handheld tool device, in a perspective view.

FIG. 2 shows a gear housing unit and a bracket holder unit of the handheld tool device, in a perspective view.

FIG. 3 shows a sectional view along a first axial direction of the gear housing unit.

FIG. 4 shows a sectional view along a second axial direction of the gear housing unit.

FIG. 5 shows a sectional view along a transverse direction of the gear housing unit.

FIG. 6 shows a holding element of the bracket holder unit in an enlarged view.

FIG. 7 shows a gear housing unit and a bracket holder unit of a further handheld tool device, in a schematic top view.

FIG. 8 shows a holding element of the bracket holder unit of FIG. 7 in an enlarged representation.

FIG. 9 shows a gear housing unit and a bracket holder unit of a further handheld tool device in a perspective view.

DETAILED DESCRIPTION

FIG. 1 shows a cordless handheld machine tool 44 a, fashioned as a battery-powered drill screwdriver, in a schematic view. Handheld machine tool 44 a has a handheld tool device.

The handheld tool device has a handheld tool housing 46 a. In the present case, handheld tool housing 46 a has been at least partly removed, in particular in upper region of handheld machine tool 44 a, for clarity.

The handheld tool device has a drive module 48 a. Drive module 48 a is realized as an electric drive motor. In addition, the handheld tool device has a tool receptacle 50 a. Tool receptacle 50 a is fashioned in the present case as a quick-release chuck. Tool receptacle 50 a is fashioned to hold a tool (not shown) for drilling and/or screwdriving. In addition, the handheld tool device has a gear module 52 a. Gear module 52 a has an input shaft (not shown). The input shaft is connected to drive module 48 a. In addition, gear module 52 a has an output shaft 54 a (cf. FIG. 3). Output shaft 54 a is connected to tool receptacle 50 a.

In addition, the handheld tool device has a tool axis of rotation 56 a. Tool axis of rotation 56 a defines an axial direction of the handheld tool device. A radial direction of the handheld tool device is, in the present case, oriented perpendicular to tool axis of rotation 56 a. Drive module 48 a, gear module 52 a, and tool receptacle 50 a are situated one after the other along tool axis of rotation 56 a. Drive module 48 a, gear module 52 a, and tool receptacle 50 a are provided to convert electrical energy of an accumulator 58 a into a rotational movement of the tool. In the present case, the accumulator is fashioned as a lithium-ion accumulator. Alternatively, it is conceivable to use a nickel-cadmium accumulator, and/or a power pack.

In addition, the handheld tool device has a gear shifting unit 60 a. Gear shifting unit 60 a has an operating element 62 a. Operating element 62 a is made so as to be capable of sliding. Gear shifting unit 60 a also has a connecting element 64 a. Connecting element 64 a connects operating element 62 a to gear module 52 a. Operating element 62 a has at least two shift positions. Each shift position is allocated to a transmission speed. The transmission speeds define a rotational speed ratio between output shaft 54 a and the input shaft.

In addition, the handheld tool device has an adjusting unit 66 a for a torque. Adjusting unit 66 a is supported and/or connected with gear module 52 a by springs 102 a, in particular pressure springs (cf. in particular FIG. 4). During operation, adjusting unit 66 a and in particular springs 102 a here bring about an axial force, in particular a coupling force, on gear module 52 a.

FIGS. 2 through 4 show a design of gear module 52 a. The handheld tool device has a gear housing unit 68 a (cf. FIG. 2). Gear housing unit 68 a is made up at least in large part of plastic. In the present case, gear housing unit 68 a is made up at least in large part of nylon. A contour of gear housing unit 68 a has an at least substantially circular cylindrical shape. Gear housing unit 68 a has, in the present case, a first gear housing 10 a and a second gear housing 12 a. First gear housing 10 a and second gear housing 12 a form separate components.

In an assembled state, first gear housing 10 a is situated on a side of gear module 52 a facing drive module 48 a. In an assembled state, first gear housing 10 a is situated on a side of gear module 52 a facing away from tool receptacle 50 a.

A contour of first gear housing 10 a has an at least substantially circular cylindrical shape. First gear housing 10 a has an at least substantially hollow cylindrical shape. First gear housing 10 a has a first opening 70 a for the input shaft. In addition, first gear housing 10 a has a guide region for connecting element 64 a of gear shift unit 60 a. Connecting element 64 a is supported on first gear housing 10 a. First gear housing 10 a has a first bulge region 20 a. First bulge region 20 a is situated on an outer side of first gear housing 10 a.

First bulge region 20 a extends completely around first gear housing 10 a, in particular in the circumferential direction. First bulge region 20 a is raised relative to a surrounding area. First bulge region 20 a is situated in an edge area of first gear housing 10 a. First bulge region 20 a is situated on a side of first gear housing 10 a facing second gear housing 12 a. First gear housing 10 a has in addition a first radial opening. In addition, first gear housing 10 a has a first axial opening. The first radial opening and the first axial opening form a common first opening 16 a. First opening 16 a is situated in an area of contact of first gear housing 10 a with second gear housing 12 a. In addition, first opening 16 a is situated in first bulge region 20 a. In addition, first gear housing 10 a has a second opening 17 a that is fashioned analogously to first opening 16 a (cf. FIG. 3). First opening 16 a and second opening 17 a are situated radially opposite one another.

In an assembled state, second gear housing 12 a is situated on a side of gear module 52 a facing away from drive module 48 a. In an assembled state, second gear housing 12 a is situated on a side of gear module 52 a facing tool receptacle 50 a. A contour of second gear housing 12 a has an at least substantially circular cylindrical shape. Second gear housing 12 a has an at least substantially hollow cylindrical shape. Second gear housing 12 a has a second opening 72 a for output shaft 54 a (cf. FIG. 3). In addition, second gear housing 12 a is surrounded at least partly by adjusting unit 66 a. Second gear housing 12 a has a second bulge region 22 a. Second bulge region 22 a is situated on an outer side of second gear housing 12 a. Second bulge region 22 a extends completely around second gear housing 12 a, in particular in the circumferential direction. Second bulge region 22 a is raised relative to a surrounding area. Second bulge region 22 a is situated in an edge area of second gear housing 12 a. Second bulge region 22 a is situated on a side of second gear housing 12 a facing first gear housing 10 a. In addition, second gear housing 12 a has a third radial opening. In addition, second gear housing 12 a has a third axial opening. The third radial opening and the third axial opening form a common third opening 18 a. Third opening 18 a is situated in an area of contact of second gear housing 12 a with first gear housing 10 a. In addition, third opening 18 a is situated in second bulge region 22 a. Third opening 18 a is situated axially opposite first opening 16 a, in particular in one of the bulge regions 20 a, 22 a. In addition, second gear housing 12 a has a fourth opening 19 a fashioned analogously to third opening 18 a (cf. FIG. 3). Third opening 18 a and fourth opening 19 a are situated radially opposite one another. Fourth opening 19 a is situated axially opposite second opening 17 a, in particular in one of the bulge regions 20 a, 22 a.

Contact surfaces, bulge regions 20 a, 22 a, and openings 16 a, 17 a, 18 a, and 19 a of gear housings 10 a, 12 a are fashioned at least substantially analogously to one another. In an assembled state, first gear housing 10 a is introduced concentrically into second gear housing 12 a. Here, the contact surfaces and/or bulge regions 20 a, 22 a of gear housings 10 a, 12 a act as stops, and thus limit a depth of insertion of gear housings 10 a, 12 a into one another. In addition, stops and/or positive-fit elements can be provided in gear housings 10 a, 12 a, preventing rotation of gear housings 10 a, 12 a relative to one another. In addition, in an assembled state bulge regions 20 a, 22 a are provided for an axial fixing of gear housings 10 a, 12 a and/or of gear module 52 a inside handheld tool housing 46 a. Here it is conceivable that handheld tool housing 46 a has at least one projection that is provided to grasp bulge regions 20 a, 22 a. Alternatively, it is conceivable that only one gear housing has a bulge region and/or an opening. In addition, a gear housing unit and/or gear housing can alternatively be made up at least partially, which may be at least in large part, and particularly completely of an arbitrary other material considered useful by a person skilled in the art, such as aluminum, and/or advantageously a plastic, in particular ABS.

The handheld tool device has in addition a gear unit 74 a (cf. in particular FIG. 3). Gear unit 74 a is fashioned as a three-speed planetary gear. Accordingly, gear unit 74 a has three planetary gear speeds. The planetary gear speeds are configured one after the other along tool axis of rotation 56 a. The planetary gear speeds are coupled to one another.

A first planetary gear speed is situated on a side of gear unit 74 a facing first opening 70 a and/or drive module 48 a. The first planetary gear speed includes a first ring gear 27 a. In an assembled state, first ring gear 27 a is situated in a first ring gear bearing region 23 a of first gear housing 10 a. A second planetary gear speed is connected after the first planetary gear speed. The second planetary gear speed includes a second ring gear 28 a. Second ring gear 28 a corresponds to a ring gear 28 a of a gear shift. In an assembled state, second ring gear 28 a is situated in a second ring gear bearing region 24 a of first gear housing 10 a and/or of second gear housing 12 a. Second ring gear 28 a is connected to gear shift unit 60 a by connecting element 64 a. Second ring gear 28 a is fashioned as a shift ring gear. Second ring gear 28 a is provided to set a selected gear ratio. Accordingly, second ring gear 28 a corresponds to gear shift element 38 a. A third planetary gear speed is situated on a side of gear unit 74 a facing second opening 72 a and/or tool receptacle 50 a. The third planetary gear speed is connected after the second planetary gear speed. The third planetary gear speed includes a third ring gear 30 a. Third ring gear 30 a corresponds to a ring gear 30 a of a torque coupling. In an assembled state, third ring gear 30 a is situated in a third ring gear bearing region 26 a of second gear housing 12 a. Third ring gear 30 a is connected to adjusting unit 66 a for the torque. Accordingly, ring gear bearing regions 24 a, 26 a are provided for accommodating ring gear 28 a of the gear shift and for accommodating ring gear 30 a of the torque coupling.

In addition, a securing unit 76 a is situated between the second planetary gear speed and the third planetary gear speed. In an assembled state, securing unit 76 a is situated in a securing bearing region 32 a of second gear housing 12 a. Securing unit 76 a has a securing ring 78 a. In addition, securing unit 76 a has a securing plate 80 a. Securing ring 78 a and securing plate 80 a are provided to secure, in the axial direction, components situated in second gear housing 12 a, in particular in a partly assembled state, whereby gear housings 10 a, 12 a can in particular be separately pre-assembled. For this purpose, securing ring 78 a is connected to second gear housing 12 a by a bayonet connection. In addition, securing ring 78 a forms a locking element 36 a for a housing-fixed locking of gear shift element 38 a, in particular of second ring gear 28 a. Here, gear shift element 38 a, in particular second ring gear 28 a, produces a force that acts on the locking element. Accordingly, securing bearing region 32 a corresponds in the present case to a bearing region of locking element 36 a. Alternatively, however, it is also conceivable that a securing element, in particular a securing ring, and a locking element are different and/or separate components. In addition, a securing ring can be connected to a gear housing by a different fastening method considered useful by a person skilled in the art.

In addition, the handheld tool device has a bracket unit 14 a. Bracket unit 14 a is provided to connect first gear housing 10 a and second gear housing 12 a to one another. In the present case, bracket unit 14 a is fashioned as a transport securing unit. Accordingly, bracket unit 14 a secures gear housings 10 a, 12 a at least during a transport. In addition, bracket holder unit 14 a is provided to produce an axial holding force on gear housings 10 a, 12 a. For this purpose, bracket unit 14 a has two holding elements 40 a, 42 a (cf. in particular also FIG. 5). Holding elements 40 a, 42 a are fashioned separately from one another. Holding elements 40 a, 42 a are fashioned analogously to one another. Holding elements 40 a, 42 a are made at least partially elastic. Holding elements 40 a, 42 a are fashioned in one piece. Holding elements 40 a, 42 a are made of a bent plate. Holding elements 40 a, 42 a are made of spring steel. Holding elements 40 a, 42 a have a material thickness of a maximum of 1.5 mm. In the present case, holding elements 40 a, 42 a have a material thickness of 0.8 mm. Holding elements 40 a, 42 a have a longitudinal extension and/or an axial extension of a maximum of 30 mm. In the present case, holding elements 40 a, 42 a have a longitudinal extension and/or axial extension of 10 mm. Holding elements 40 a, 42 a have a transverse extension of a maximum of 30 mm. In the present case, holding elements 40 a, 42 a have a transverse extension of 10 mm. Holding elements 40 a, 42 a are, regarded in a top view, at least substantially rectangular, in particular square. Alternatively, it is conceivable that holding elements are made oblong, regarded in a top view. In the present case, holding elements 40 a, 42 a, regarded in a side view, are at least substantially U-shaped. Here, each holding element 40 a, 42 a has two holding arms 82 a, 84 a, and a connecting web 86 a. In the present case, holding arms 82 a, 84 a and connecting web 86 a enclose an angle smaller than 90°. Holding elements 40 a, 42 a, and in particular holding arms 82 a, 84 a are provided in order to exert, in an assembled state, an axial holding force on gear housing 10 a, 12 a. For simple assembly and/or disassembly, each of the holding elements 40 a, 42 a, in particular connecting web 86 a, additionally has a through-opening 88 a.

In the present case, bracket holder unit 14 a is provided for tangential assembly and disassembly. For assembly and/or disassembly, holding elements 40 a, 42 a are pressed in a tangential direction into openings 16 a, 17 a, 18 a, 19 a. In an assembled state, a first holding element 40 a is situated in first opening 16 a and in third opening 18 a. In an assembled state, a second holding element 42 a is situated in second opening 17 a and in fourth opening 19 a. Accordingly, in the assembled state holding elements 40 a, 42 a are situated radially opposite one another. In the assembled state, holding elements 40 a, 42 a, and in particular holding arms 82 a, 84 a press axially opposite walls of openings 16 a, 17 a, 18 a, 19 a against one another, and in this way in particular exert the holding force on gear housings 10 a, 12 a. Alternatively, however, it is also conceivable to fasten holding elements by an axial assembly and/or disassembly.

Accordingly, in the assembled state bracket holder unit 14 a is situated in a contact region of gear housings 10 a, 12 a, in at least one opening 16 a, 17 a, 18 a, 19 a of gear housings 10 a, 12 a, and at least partly in at least one bulge region 20 a, 22 a. In addition, bracket unit 14 a, in particular holding elements 40 a, 42 a, is situated at least partly in an axial segment of second ring gear bearing region 24 a, of third ring gear bearing region 26 a, of securing bearing region 32 a, and of bearing region of locking element 36 a. In addition, bracket unit 14 a, in particular holding elements 40 a, 42 a, is situated in an axial segment of supporting unit 98 a. In addition, bracket unit 14 a, in particular holding elements 40 a, 42 a, is situated axially between gearshift unit 60 a and adjusting unit 66 a.

The handheld tool device additionally includes a supporting unit 98 a. Supporting unit 98 a includes securing ring 78 a and/or locking element 36 a, the bayonet connection, and a plurality of openings 100 a of second gear housing 12 a. Supporting unit 98 a is provided to absorb the axial force occurring during operation in order to relieve stress on bracket holder unit 14 a. In the present case, supporting unit 98 a is provided to absorb an axial force of third ring gear 30 a. For this purpose, securing ring 78 a and/or locking element 36 a is supported immediately on second gear housing 12 a and indirectly on first gear housing 10 a. In this way, a material thickness of the at least one holding element 40 a, 42 a can advantageously be kept small. Alternatively, however, it is also conceivable that a bracket holder unit of a pure transport securing unit is fashioned differently, and in particular is also provided during operation to absorb a large part of the occurrent forces. For further details relating to the realization of supporting unit 98 a, of securing ring 78 a, and/or of locking element 36 a, reference is made to DE 10 2011 081 661 A1, whose disclosure is here explicitly referred to.

FIGS. 6 through 8 show a further exemplary embodiment of the present invention. The following descriptions and the drawings are limited substantially to the differences between the exemplary embodiments, and, with regard to components having identical designations, in particular with regard to components having identical reference characters, reference is fundamentally also made to the drawings and/or to the description of the other exemplary embodiments, in particular of FIGS. 1 through 5. In order to distinguish the exemplary embodiments, the letter ‘a’ has been appended to the reference characters of the exemplary embodiment in FIGS. 1 through 5. In the exemplary embodiments of FIGS. 6 through 8, the letter ‘a’ is replaced by the letters ‘b’ and ‘c.’

In FIGS. 6 and 7, a first exemplary embodiment of the present invention is shown. The letter ‘b’ is appended to the exemplary embodiment of FIGS. 6 and 7. The further exemplary embodiment differs from the preceding exemplary embodiment at least substantially by a holding element 40 b, 42 b of a bracket unit.

In the present case, holding elements 40 b, 42 b are provided for axial assembly and/or disassembly. In addition, holding arms 82 b, 84 b of holding elements 40 b, 42 b each have an additional locking opening 90 b, 92 b. Locking openings 90 b, 92 b are provided to accept, in an assembled state, corresponding locking projections 94 b, 96 b of a first gear housing 10 b and/or of a second gear housing 12 b.

FIGS. 8 and 9 show a further exemplary embodiment of the present invention. The letter ‘c’ is appended to the exemplary embodiment of FIGS. 8 and 9. The further exemplary embodiment differs from the preceding exemplary embodiment at least substantially by a fastening direction of a holding element 40 c, 42 c of a bracket unit.

Holding elements 40 c, 42 c correspond to holding elements 40 b, 42 c of the preceding exemplary embodiment. However, in the present case holding elements 40 c, 42 c are provided for a tangential assembly and/or disassembly. 

What is claimed is:
 1. A handheld tool device, comprising: at least one first gear housing having a first bulge region, the first bulge region being embodied in one piece with the at least one first gear housing and having at least one first axial and radial recess; at least one second gear housing having a second bulge region, the second bulge region being embodied in one piece with the at least one second gear housing and having at least one second axial and radial recess; and a bracket holder unit to connect the at least one first gear housing to the at least one second gear housing, the bracket holder unit being separate from the at least one first gear housing and the at least one second gear housing; wherein, in the assembled state, the bracket holder unit is situated at least in an area of contact of the at least one first gear housing and the at least one second gear housing in the first recess of the at least one first gear housing and in the second recess of the at least one second gear housing, wherein the first recess and the second recess are situated axially opposite one another, wherein the bracket holder unit includes at least one holding element having two holding arms and a connecting web connecting the two holding arms, wherein the at least one holding element is configured to embrace the first and second gear housing such that respective ones of the two holding arms engage with the first bulge region of the at least one first gear housing and the second bulge region of the second gear housing to exert an axial holding force on the at least one first gear housing and the at least one second gear housing, wherein the at least one holding element is situated in the first recess of the first bulge region and in the second recess of the second bulge region such that the at least one holding element does not project beyond the first bulge region and the second bulge region.
 2. The handheld tool device of claim 1, wherein the at least one holding element is configured for a tangential assembly and/or a tangential disassembly.
 3. The handheld tool device of claim 1, wherein the at least one holding element has an axial extension less than 30 mm.
 4. The handheld tool device of claim 1, wherein the ring gear bearing region is configured for accommodating a ring gear of a gear shift and/or for accommodating a ring gear of a torque coupling.
 5. The handheld tool device of claim 1, wherein at least one of the first and second gear housings has a securing bearing region in whose axial segment the bracket holder unit is at least partially situated.
 6. The handheld tool device of claim 1, wherein at least one of the first and second gear housings has a bearing region of a locking element for a housing-fixed locking of a gear shift element, the bracket holder unit being situated at least partially in the axial segment of the bearing region.
 7. The handheld tool device of claim 1, further comprising: a supporting unit configured to absorb at least one axial force occurring during operation inside at least one of the first and second gear housings to relieve stress on the bracket holder unit.
 8. The handheld tool device of claim 1, wherein at least one of the first and second gear housings is to accommodate an at least two-speed planetary gear.
 9. The handheld tool device of claim 1, wherein the bracket holder unit has at least two holding elements fashioned separately from one another, which are provided to exert an axial holding force on the at least one of the first and second gear housings.
 10. The handheld tool device of claim 9, wherein in an assembled state the at least two holding elements are situated radially opposite one another.
 11. The handheld tool device of claim 9, wherein the first of the at least two holding elements is situated in the first recess and the second recess and the second of the at least two holding elements is situated in a third recess and a fourth recess, wherein the third recess is situated in the first bulge region of the first gear housing and the fourth recess is situated in the second bulge region of the second gear housing.
 12. The handheld tool device of claim 1, wherein the holding arms include at least one locking element which is configured to engage with at least one corresponding locking element provided on the at least one first and second gear housings.
 13. The handheld tool device of claim 1, wherein the at least one holding element is at least partially elastic.
 14. The handheld tool device of claim 1, wherein the at least one holding element is configured for an axial assembly and/or an axial disassembly. 